CN113116383A - Method, system and storage medium for rapid measurement of ultrasound device - Google Patents

Abstract

The invention relates to the field of ultrasonic image processing, in particular to a rapid measurement method and system of ultrasonic equipment and a storage medium. The rapid measurement method of the ultrasonic equipment comprises the following steps: determining a measurement component; acquiring an indication message that an activation point on the measurement component is in a state to be measured; according to the indication message, carrying out corresponding deformation processing on the measurement assembly so that the deformed measurement assembly conforms to the range to be measured of the ultrasonic image; determining the dimensions of the measurement assembly after deformation. Wherein the system is used to perform a fast measurement method of an ultrasound device. Wherein the storage medium has stored therein computer instructions for causing a computer to execute the method for rapid measurement of an ultrasound device. The invention can dynamically deform through the measuring component to solve the technical problem that the measuring precision of the related technology cannot meet the requirement.

Description

Method, system and storage medium for rapid measurement of ultrasound device

Technical Field

The invention relates to the field of ultrasonic image processing, in particular to a rapid measurement method and system of ultrasonic equipment and a storage medium.

Background

As ultrasonic devices are increasingly miniaturized and portable, touch screens capable of assisting input and display are widely used in ultrasonic devices. For the ultrasound image acquired by the ultrasound device, the touch screen has the functions of displaying and assisting input, and needs to be capable of selecting the measurement area or line segment of the ultrasound image, so that the system can calculate the size of the selected measurement area, and the convenience of reading the film by a doctor can be further improved.

In the related art, the measurement area or line segment of the ultrasound image is selected in a sliding manner by touching the touch screen with a medium including a finger. However, in this way, the area of the contact area between the medium including the finger and the touch screen is much larger than the area of the measurement point on the measurement area or line segment, so that the measurement accuracy cannot meet the requirement.

Disclosure of Invention

The invention provides a rapid measurement method, a rapid measurement system and a storage medium of ultrasonic equipment, so that the technical problem that the measurement precision of the related technology cannot meet the requirement is solved.

According to the technical scheme provided by the invention, as a first aspect of the invention, a rapid measurement method of an ultrasonic device is provided, which comprises the following steps:

determining a measurement component;

acquiring an indication message for enabling an activation point on the measurement component to be in a state to be measured;

according to the indication message, performing corresponding deformation processing on the measurement assembly so that the deformed measurement assembly conforms to the range to be measured of the corresponding object to be detected in the ultrasonic image;

determining the dimensions of the measurement assembly after deformation.

Optionally, the measuring assembly comprises at least two structure points;

the activation point is triggered by at least one structure point in the measurement assembly.

Optionally, the process of triggering the structure point to form the activation point includes:

when a medium contacts a touch screen, acquiring trigger information formed by each pixel point in a contact area;

traversing the pixel value of each pixel point in the contact area according to the trigger information, and judging whether a structure point exists in the contact area;

and if the contact area has the structure point, triggering the structure point as an activation point, so that the activation point is out of the contact area.

Optionally, after the structure point is triggered to form the activation point, a prompt box centered on the activation point is generated;

the acquiring the indication message that the activation point on the measurement component is in the state to be measured includes:

and acquiring an indication message that the activation point on the measurement component is in a state to be measured through the prompt box.

Optionally, the message indicating that the active point is in the state to be measured includes: and the activation point is in the moving direction information of the state to be moved.

Optionally, the performing, according to the indication message, corresponding deformation processing on the measurement component so that the deformed measurement component conforms to a range to be measured of the corresponding object to be detected in the ultrasound image includes:

according to the moving direction information in the indication message, carrying out amplification deformation processing, reduction deformation processing or rotation deformation processing on the measurement assembly to obtain a deformation measurement assembly;

and enabling the interval determined by the deformation measuring component to be matched with the range to be measured of the corresponding object to be detected in the ultrasonic image.

As a second aspect of the present invention, there is provided a rapid measurement system of an ultrasound apparatus for performing a rapid measurement method of an ultrasound apparatus according to the first aspect of the present invention, including:

a measurement component determination module for determining a measurement component;

the indication message acquisition module is used for acquiring an indication message which enables an activation point on the measurement component to be in a state to be measured;

the measuring component deformation module is used for carrying out corresponding deformation processing on the measuring component according to the indication message so as to enable the deformed measuring component to conform to the range to be measured of the corresponding object to be detected in the ultrasonic image;

and the size calculation module is used for determining the size of the measurement assembly after deformation.

Optionally, at least one size calculation algorithm is preset in the size calculation module.

Optionally, the measurement component deformation module is configured to perform an amplification deformation process, a reduction deformation process, or a rotation deformation process on the measurement component according to the moving direction information in the indication message, so as to obtain the deformation measurement component.

As a third aspect of the present invention, there is provided a rapid measurement storage medium of an ultrasound apparatus having stored therein computer instructions for causing a computer to execute the rapid measurement method of an ultrasound apparatus according to the first aspect of the present invention.

From the above, it can be seen that the rapid measurement method, system and storage medium for ultrasound equipment provided by the present invention have the following advantages compared with the prior art:

the method comprises the steps that a user needs to measure and display the size of an area to be measured or a line segment to be measured in an ultrasonic image, the determined measuring component can be dynamically deformed, and further position coordinates of structure points on the measuring component are changed, so that the measuring component is matched with the area to be measured or the line segment to be measured of a corresponding object to be measured in the ultrasonic image, the size of the area to be measured or the line segment to be measured in an acoustic image can be rapidly judged through measuring the size of the deformed measuring component, and the operation experience of the user is improved while the measuring precision is improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

Fig. 1 is a flow chart of a first aspect of the present invention.

Fig. 2 is a schematic diagram illustrating a detailed operation of step S12 in embodiment 1 of the first aspect of the present invention.

Fig. 3 is a schematic diagram showing a detailed operation of step S13 in embodiment 1 of the first aspect of the present invention.

Fig. 4 is a schematic diagram illustrating a detailed operation of step S15 in embodiment 1 of the first aspect of the present invention.

Fig. 5 is a schematic diagram illustrating a detailed operation of step S22 in embodiment 2 of the first aspect of the present invention.

Fig. 6 is a block diagram of an embodiment of the second aspect of the present invention.

100. Prompt box, 200 measuring component, 300 area to be measured.

Detailed Description

The technical solutions in the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, are within the scope of the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; the connection can be mechanical connection or electrical connection; the two elements may be directly connected or indirectly connected through an intermediate medium, or may be communicated with each other inside the two elements, or may be wirelessly connected or wired connected. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In addition, the technical features involved in the different embodiments of the present invention described below may be combined with each other as long as they do not conflict with each other.

As a first aspect of the present invention, there is provided a rapid measurement method of an ultrasound apparatus, which can be applied to an ultrasound apparatus, for example, a palm-top ultrasound apparatus having a touch screen, a portable ultrasound apparatus, and the like. As shown in fig. 1, the method for rapid measurement of an ultrasonic apparatus includes the steps of:

s1: determining a measurement component 200;

in this embodiment, the measuring component 200 may be a line segment for measuring length, or a closed region figure for measuring region area or perimeter; the measurement assembly 200 includes at least two structural points.

After a user selects a specific measuring component 200 on the touch screen according to requirements, the system can identify and determine the type of the measuring component 200, the measuring component 200 can appear on the touch screen, and coordinates of the structure point of the measuring component 200 in the touch screen coordinate system can be determined and acquired by the system.

In addition, the measurement assembly 200 may be determined in any manner by one skilled in the art and will not be described in detail herein.

S2: acquiring an indication message for putting an activation point on the measurement component 200 in a state to be measured;

after determining the measurement component 200 according to the user's needs, the user touches a structure point in the measurement component 200 through a medium such as a finger, and the structure point can be triggered as an activation point; when a user touches a screen near an activation point, including the position of the activation point, through a medium such as a finger and the like, and performs sliding and other operations, the system can acquire an indication message that the activation point is in a state to be measured; in contrast, when the structure point is not activated as the activation point, even if the user touches a screen near the activation point, including the position of the activation point, with a medium such as a finger and performs an operation such as sliding, the system cannot obtain an indication message that the activation point is in a state to be measured.

In addition, when an activation point is dragged outside the screen active area of the touch screen, the activation point is located at the edge of the screen active area by default.

S3: according to the indication message, performing corresponding deformation processing on the measurement assembly 200, so that the deformed measurement assembly 200 conforms to the range to be measured of the corresponding object to be detected in the ultrasonic image;

for example, after the doctor acquires the ultrasound image through the touch screen, the doctor needs to measure the distance between two specific positions in the ultrasound image, or needs to measure the area and the perimeter of a certain specific area in the ultrasound image, and the certain specific area between the two specific positions in the ultrasound image or in the ultrasound image is the measurement range of the ultrasound image, and the measurement assembly 200 is made to fit the measurement range of the ultrasound image by using the deformation of the measurement assembly 200, so that the size of the measurement range of the ultrasound image can be judged according to the size of the measurement assembly 200 after the deformation is measured. In some embodiments, the object to be detected may include: an organ to be tested, a tissue to be tested, and the like. The organ to be tested may include, but is not limited to, brain, lung, heart, kidney, liver, etc. The tissue to be tested may include, but is not limited to, epithelial tissue, connective tissue, neural tissue, muscle tissue, and the like. In some embodiments, different probes may be used depending on the type of object to be detected, for example, a convex array probe may be used for liver or pregnant woman detection, a phased array probe may be used for heart detection, etc.

In some embodiments, the ultrasound graphics may also be previously obtained by the user from the ultrasound device and displayed on the touch screen.

S4: the dimensions of the measurement assembly 200 after deformation are determined.

By acquiring coordinates of each structure point in the deformed measuring assembly 200, parameters including length, perimeter or area of the corresponding measuring assembly 200 are calculated according to a preset algorithm, and the calculated parameters of the measuring assembly 200 are used as parameters of a range to be measured of the ultrasonic image.

In this embodiment, a user needs to measure and display the size of the area to be measured or the line segment to be measured in the ultrasound image on the touch screen, the determined measurement assembly 200 can be dynamically deformed, so that the position coordinates of the structure points on the measurement assembly 200 are changed, the measurement assembly 200 is matched with the area to be measured or the line segment to be measured in the ultrasound image, the size of the area to be measured or the line segment to be measured in the acoustic image can be quickly determined by measuring the deformed size of the measurement assembly 200, and the measurement accuracy and the operation experience of the user are improved.

For example, example 1

A method for rapidly measuring an ultrasonic device at two positions in an ultrasonic image is provided, and with reference to FIGS. 2 to 4, the method comprises the following steps:

s11: determining ab line segment as measurement component 200;

when a user needs to determine the distance between two positions in an ultrasound image, the position a and the position B, an ab line segment for measuring the length can be selected as the measuring component 200, i.e. the structure points of the measuring component 200 include an a end point and a B end point at both ends of the line segment.

S12: triggering a b end point, wherein the b end point forms an activation point due to being triggered, and a prompt box 100 is formed around the b end point, the size and the shape of the prompt box 100 are adjustable, and the center of the prompt box 100 is the b end point; when a user touches the area of the prompt box 100 with a finger, the b endpoint is in a state to be measured, and when the user drags the prompt box 100 while touching the area of the prompt box 100 with the finger, the system acquires drag direction information and drag distance information of the drag prompt box 100, that is, movement direction information and movement distance information of the b endpoint.

The user drags the operation action in the area of the prompt box 100 on the touch screen, that is, an instruction for enabling the activation point to be in a state to be measured is sent to the system; the system can obtain an indication that the activation point is in a state to be measured.

S13: receiving the instruction in S12, performing corresponding deformation processing on the measurement component 200ab segment, so that the a endpoint is stationary and the B endpoint moves to the B position, and then performing corresponding amplification deformation processing on the measurement component 200ab segment from the position in fig. 2 to stretch the measurement component to the shape and position in fig. 3.

S14: triggering the a end point by adopting the steps as described in S12; similarly, the a end point forms an activation point due to being triggered, and a prompt box 100 is formed around the a end point, the size and the shape of the prompt box 100 are adjustable, and the center of the prompt box 100 is the a end point; when a user touches the area of the prompt box 100 with a finger, the a-end point is in a state to be measured, and when the user drags the prompt box 100 while touching the area of the prompt box 100 with the finger, the system acquires drag direction information and drag distance information of the drag prompt box 100, that is, movement direction information and movement distance information of the a-end point.

S15: receiving the instruction of S14, performing corresponding deformation processing on the measurement component 200ab segment, so that the b endpoint is stationary and the a endpoint moves to the a position, and then performing corresponding reduction deformation processing on the measurement component 200ab segment from the position of fig. 3 to stretch the measurement component to the shape and position of fig. 4;

so that the ab-segment position coincides with two positions in the ultrasound image that the user needs to determine, namely, the a position and the B position.

S16: the distance between the position a and the position B can be determined quickly by obtaining the real-time coordinates of the end point a and the end point B of the measurement component 200ab segment, and calculating the length of the measurement component 200ab segment after deformation, i.e., the position shown in fig. 4, according to a preset algorithm.

In the process, a prompt box 100 with an excitation point as the center is formed, and the range of touch judgment is expanded, so that no matter what medium is adopted by a user to trigger the dragging of the activation point, the size of deformation of the measurement assembly 200 cannot be influenced, and the measurement accuracy can be ensured. In addition, because the range of touch judgment is enlarged, no matter the user drags the activation point through a finger or other media, the activation point can be prevented from being blocked, and the position of the activation point can be observed in real time.

Example 2

A fast measurement method of an ultrasonic apparatus for measuring a region 300 to be measured is provided, referring to fig. 5, including the steps of:

s21: determining a cdef seal area as measurement component 200;

when a user needs to determine the area of the region 300 to be measured in the ultrasound image, the cdef closed region can be selected as the measurement component 200, that is, the structure points of the measurement component 200 include points c, d, e and f at the two ends of the line segment.

S22: triggering an e point, wherein the e point forms an activation point due to being triggered, and a rectangular prompt box 100 is formed around the e point, the size and the shape of the prompt box 100 are adjustable, and the center of the prompt box 100 is the e point; when the user touches the area of the prompt box 100 with a finger, the point e is in a state to be measured, and when the user drags the prompt box 100 while touching the area of the prompt box 100 with a finger, the system acquires drag direction information and drag distance information of the drag prompt box 100, that is, movement direction information and movement distance information of the point e.

S23: and receiving the moving direction information and the moving distance information of the point e in the step S12, performing corresponding deformation processing on the cdef closed area of the measurement component 200, so that the point a opposite to the point e is stationary, the rest structural points move along with the movement of the point e, and finally the point e falls on the edge of the to-be-measured area 300 in a certain direction in the ultrasonic image, namely the rightmost edge position of the to-be-measured area 300, so that the cdef closed area of the measurement component 200 is subjected to amplification deformation processing.

S24: s22 and S23 are repeated so that point a, point d, and point f are located at the leftmost edge position, the uppermost edge position, and the lowermost edge position of the region 300 to be measured, respectively, and the cdef sealing region of the measurement component 200 coincides with the region 300 to be measured.

S24: the area of the area 300 to be measured can be quickly determined by obtaining real-time coordinates of the point a, the point d, the point e and the point f of the sealed area of the measuring component 200cdef and calculating the deformed area of the sealed area of the measuring component 200cdef according to a preset algorithm.

In the process, a prompt box 100 with an excitation point as the center is formed, and the range of touch judgment is expanded, so that no matter what medium is adopted by a user to trigger the dragging of the activation point, the size of deformation of the measurement assembly 200 cannot be influenced, and the measurement accuracy can be ensured. In addition, because the range of touch judgment is enlarged, no matter the user drags the activation point through a finger or other media, the activation point can be prevented from being blocked, and the position of the activation point can be observed in real time.

Example 3

On the basis of the foregoing embodiment, further, the process of triggering the structure point to form the activation point includes:

when a medium contacts a touch screen, acquiring trigger information formed by each pixel point in a contact area;

traversing the pixel value of each pixel point in the contact area according to the trigger information, and judging whether a structure point exists in the contact area;

and if the contact area has the structure point, triggering the structure point as an activation point, so that the activation point is out of the contact area.

As a second aspect of the present invention, a rapid measurement system of an ultrasound apparatus is provided.

The fast measurement system of the ultrasound device is for performing an embodiment of the method according to the first aspect of the invention, with reference to fig. 6, comprising:

a measurement component determination module for determining a measurement component 200; wherein the measuring assembly 200 is present on the touch screen and the coordinates of the structure points of the measuring assembly 200 in the touch screen coordinate system can also be determined and acquired by the system.

An indication message acquiring module, configured to acquire an indication message that an activation point on the measurement component 200 is in a state to be measured;

after determining the measurement component 200 according to the user's needs, the user touches a structure point in the measurement component 200 through a medium such as a finger, and the structure point can be triggered as an activation point; when a user contacts the screen near the activation point, including the position of the activation point, through a medium such as a finger and slides, the indication message acquisition module can acquire an indication message of the state to be measured of the activation point; on the contrary, when the structure point is not activated to become the activation point, even if the user touches the screen near the activation point, including the position of the activation point, by a medium such as a finger and performs an operation such as sliding, the indication message acquisition module cannot acquire the indication message that the activation point is in the state to be measured.

In the game embodiment, when the activation point is dragged to be out of the screen active area of the touch screen, the activation point is located at the edge of the screen active area by default.

The measuring component deformation module is used for performing corresponding deformation processing on the measuring component 200 according to the indication message so that the deformed measuring component 200 conforms to the range to be measured of the ultrasonic image;

after a doctor obtains an ultrasound image through a touch screen, the doctor needs to measure the distance between two specific positions in the ultrasound image, or needs to measure the area and the perimeter of a certain specific area in the ultrasound image, the certain specific area between the two specific positions in the ultrasound image or the certain specific area in the ultrasound image is the measurement range of the ultrasound image, the measurement assembly 200 is deformed by using the measurement assembly deformation module, the measurement assembly 200 is matched with the range to be measured of the ultrasound image, and therefore the size of the range to be measured of the ultrasound image can be judged according to the size of the measurement assembly 200 after deformation.

A dimension calculation module for determining the dimensions of the measurement assembly 200 after deformation. By acquiring coordinates of each structure point in the deformed measuring assembly 200, parameters including length, perimeter or area of the corresponding measuring assembly 200 are calculated according to a preset algorithm, and the calculated parameters of the measuring assembly 200 are used as parameters of a range to be measured of the ultrasonic image.

At least one size calculation algorithm is preset in the size calculation module.

By acquiring coordinates of each structure point in the deformed measuring assembly 200, parameters including length, perimeter or area of the corresponding measuring assembly 200 are calculated according to a preset algorithm, and the calculated parameters of the measuring assembly 200 are used as parameters of a range to be measured of the ultrasonic image.

As a third aspect of the present invention

There is provided a fast measurement storage medium of an ultrasound apparatus for causing a fast measurement system of the ultrasound apparatus to perform the fast measurement method of the ultrasound apparatus according to the first aspect of the present invention.

It should be understood that the above examples are only for clarity of illustration and are not intended to limit the embodiments. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. And obvious variations or modifications therefrom are within the scope of the invention.

Claims (10)

1. A rapid measurement method of an ultrasonic device is characterized by comprising the following steps:

determining a measurement component;

acquiring an indication message for enabling an activation point on the measurement component to be in a state to be measured;

according to the indication message, performing corresponding deformation processing on the measurement assembly so that the deformed measurement assembly conforms to the range to be measured of the corresponding object to be detected in the ultrasonic image;

determining the dimensions of the measurement assembly after deformation.

2. The method for rapid measurement of ultrasound equipment according to claim 1, wherein the measurement assembly comprises at least two structure points;

the activation point is triggered by at least one structure point in the measurement assembly.

3. The method for rapid measurement of an ultrasound device according to claim 2, wherein triggering the structure points to form the activation points comprises:

when a medium contacts a touch screen, acquiring trigger information formed by each pixel point in a contact area;

traversing the pixel value of each pixel point in the contact area according to the trigger information, and judging whether a structure point exists in the contact area;

and if the contact area has the structure point, triggering the structure point as an activation point, so that the activation point is out of the contact area.

4. The method for rapid measurement of an ultrasound device according to claim 2, wherein after the structure point is triggered to form the activation point, a prompt box centered on the activation point is generated;

the acquiring the indication message that the activation point on the measurement component is in the state to be measured includes:

and acquiring an indication message that the activation point on the measurement component is in a state to be measured through the prompt box.

5. The method for rapid measurement of an ultrasound apparatus according to claim 1, wherein the message indicating that the active point is in a state to be measured includes: and the activation point is in the moving direction information of the state to be moved.

6. The method for rapid measurement of an ultrasound apparatus according to claim 5, wherein the performing corresponding deformation processing on the measurement component according to the indication message so that the deformed measurement component conforms to a range to be measured of a corresponding object to be detected in an ultrasound image comprises:

according to the moving direction information in the indication message, carrying out amplification deformation processing, reduction deformation processing or rotation deformation processing on the measurement assembly to obtain a deformation measurement assembly;

and enabling the interval determined by the deformation measuring component to be matched with the range to be measured of the corresponding object to be detected in the ultrasonic image.

7. A rapid measurement system of an ultrasonic apparatus, wherein the rapid measurement system of the ultrasonic apparatus is used for performing a rapid measurement method of the ultrasonic apparatus according to any one of claims 1 to 6, and comprises:

a measurement component determination module for determining a measurement component;

the indication message acquisition module is used for acquiring an indication message which enables an activation point on the measurement component to be in a state to be measured;

the measuring component deformation module is used for carrying out corresponding deformation processing on the measuring component according to the indication message so as to enable the deformed measuring component to conform to the range to be measured of the corresponding object to be detected in the ultrasonic image;

and the size calculation module is used for determining the size of the measurement assembly after deformation.

8. The system of claim 7, wherein at least one dimension calculation algorithm is pre-programmed into the dimension calculation module.

9. The system of claim 7, wherein the measurement component deformation module is configured to perform an amplification deformation process, a reduction deformation process, or a rotation deformation process on the measurement component according to the movement direction information in the indication message to obtain a deformation measurement component.

10. A fast measurement storage medium of an ultrasound apparatus, wherein the fast measurement storage medium of the ultrasound apparatus stores therein computer instructions for causing a computer to execute a fast measurement method of the ultrasound apparatus according to any one of claims 1 to 6.

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